SU1278537A1 - Cryogenic reservoir - Google Patents

Abstract

This invention relates to cryogenic tanks and solves the problem of increasing their efficiency by increasing the reliability of the adsorbent. In a cryogenic tank in an evacuated cavity between the casing and the inner vessel, there is an adsorption chamber, which can be made of several sections, the cavities of which are free from the adsorbent are interconnected to form a collector and communicated with the evacuated cavity through an opening blocked by a motorized gate . The adsorbent is placed in destructible packaging, made, for example, in the form of discontinuous membranes and fixed on the wall of the inner vessel. A tubular coil is disposed in the adsorbent layer for supplying the working agent — gas, connected to the pushers with knives installed opposite the membranes and to the valve drive. When gas is supplied to the coil with a certain pressure, it drives the pushers, which open the packaging of the adsorbent and communicate it to the evacuated cavity, i.e. provide the work of the adsorbent to pump out residual gases. When a green gas is supplied to the coil, the adsorbent is regenerated without heating the internal vessel. When gas is supplied to the coil with a different pressure, it is possible to close the collector opening with a valve and check the tightness of the cryogenic tank. 2 hp f-ly, 1 ill. | 00 SP oo

Description

The invention relates to a cryogenic technique, namely, tanks for storing and transporting such cryogenic liquids such as liquid oxygen, nitrogen, argon, and others, and can be used in cryoabsorption vacuum pumps. The aim of the invention is to increase efficiency by increasing the reliability of the adsorbent. The drawing schematically shows the proposed device. The cryogenic tank contains an internal vessel 1 for a cryogenic liquid and a casing 2, in the evacuated cavity 3 between which the thermal insulation 4 is located and the adsorption chamber made of sections 5 and 6. The latter, in turn, consist of two compartments blocked by gas-permeable filters 7 and separated by destructible packaging — bursting membranes 8. The compartments of sections fastened on the inner vessel are filled with adsorbent 9, each has pushers 10 of one-time action, for example, in the form of corrugated plastic pockets, on heat insulating bases 11 and connected by nozzles 12 to tubular coils 13, into which working agent 14 is fed — heating gas — and discharged through nozzle 15. Pushers are connected by means of rods 16 to knives 17, in the initial position contacting with rupture membranes, and after the pushers have triggered, sections 18 that are being pushed out into the second compartments with parts cut off from the membranes, together with the second compartments of the adsorbent sections, are free from the adsorbent and hermetically interconnected to form a common collector 19, overlapped with ends by covers 20. A hole 21 is made in the collector with a seal 22, which communicates with the evacuated cavity of the tank and is blocked by a valve 23 that is connected by a shaft 24 to an actuator 25, for example, a bellows connected by nozzles 26 to the coil 13. The spring 27 provides a normally open the position of the flap 23. A manifold 28 is installed on the manifold 19 to measure the pressure of the residual gases in the closed chamber. The device works as follows. During the installation of the cryogenic tank on its inner vessel 1, structurally self-formed sections, for example sections 5 and 6, are assembled into a single adsorption chamber, in which the compartments in contact with the internal vessel are filled with regenerated adsorbent 9 and a dry gas other than indicator gas, used when monitoring the tightness of a tank, for example, with nitrogen. At the same time, the second compartments of the sections, free from the adsorbent and connected directly to each other or via compensating inserts (angular or straight), form a single sealed manifold 19 communicating with the cavity 3 of the reservoir through the opening 21 periodically blocked by the damper 23. When evacuating cavity 3 and the collector 19 of the chamber after assembling the tank into the coils 13 through the nozzles 14 or 15 is supplied with gas under the pressure of the first stage, which actuates the pushers 10 of a one-time action, for example corrugated plates astichnye pockets. The pins 16 connected to the pushers and the knives 17 in the initial position are in contact with the membranes 8, and after the pushers act, they move into the second compartments of the sections, the section 18 of the membranes and together the adsorbent 9 with the evacuated cavity 3 of the tank. The heat insulating bases 11 of the pushers 10 prevent the condensation of gas supplied through the coils 13 and the pusher cavities into the valve actuator 25 when the internal vessel is filled with cryogenic liquid 1. If necessary, operational monitoring of the tightness of the reservoir that occurs during its operation and when assessing the performance of the adsorbent the aperture 21 is blocked by a damper 23 connected by a spring-loaded brush 24 with an actuator 25, for example, a bellows when gas is supplied through the pipes 14 or 15 under the pressure of the second Upenu, higher than the pressure of the first stage. After the evacuation of the cavity 3 by the adsorbent as a result of the chamber shutting off by the valve 23, conditions are created for determining the tightness of the tank by one of the known methods, for example, manometric for increasing the pressure of residual gases in cavity 3, recorded by a pressure gauge mounted on the casing (not shown). The overlap of the chamber with the shutter 23 also allows the operability of the adsorbent during the operation of the tank to be cordoned off by means of a pressure gauge transducer 28 registering the residual gas limit pressure and the speed it reaches in the manifold of the adsorption chamber. When the adsorbent is regenerated, the cryogenic liquid is drained from the inner vessel 1 and heating gas is fed through the pipe 14 to the tubular coil 13, which is discharged through the pipe 15. At the same time, the chamber collector 19 is evacuated through the open hole 21 and through the cavity 3 of the tank. The tubular coil used in the device allows not only the regeneration of the adsorbent to be carried out directly by heating without heating the entire internal vessel, but also to control the operation of the device's executive bodies.

Claims (3)

Invention Formula . A cryogenic tank containing an internal cryogenic liquid vessel and a casing, in the evacuated cavity between which there is thermal insulation and a chamber with an adsorbent placed in a destroyed package on the wall of the internal vessel, characterized in that, in order to increase efficiency by increasing the reliability of the adsorbent, the chamber is equipped with a tubular coil for supplying the working agent, placed in the layer of adsorbent by pushers with knives that interact with the package to be destroyed and connected to the tubular serpent Eviku. 2. The tank according to claim 1, distinguished by the fact that the chamber is made of sections, each of which contains a tubular coil and a pusher, the cavity of the sections, free of the adsorbent, communicate with each other to form a common collector and with the evacuated cavity through the hole and equipped with a valve with a drive mounted opposite the aperture, while the valve actuator is connected to a tubular coil. 3. Reservoir for PP. 1 and 2, characterized in that the package being destroyed and made in the form of rupture membranes.